Deck 13: Viruses, Viroids, and Prions

A) nucleic acid.
B) capsid.
C) envelope.
D) tail.
E) spikes.

A) suckers.
B) pili.
C) cilia.
D) spikes.
E) hooks.

A) all produced simultaneously AND are used to customize the cell for viral production.
B) produced in a sequential manner AND are used to destroy the host cell.
C) are strictly host enzymes AND are used to customize the cell for viral production.
D) produced in a sequential manner AND are used to customize the cell for viral production.
E) all produced simultaneously AND are used to destroy the host cell.

A) viralcidens.
B) bacteriocidins.
C) bacterialogens.
D) bacteriophages.
E) virophages.

A) pathogenic virus.
B) subviral particle.
C) complete, extracellular virus particle.
D) enveloped virus particle.
E) non-enveloped virus particle.

A) Capsid fragments around the nucleic acid.
B) Protein fibers at the end of the phage tail.
C) Pili of the envelope.
D) Spikes of the envelope.
E) Spikes of the cell wall.

A) scavenging glucose.
B) gaining ATP from the mitochondria.
C) metabolically inert.
D) using cilia to move to the next host.
E) replicating by binary fission.

A) lipid, protein, and either RNA or DNA.
B) protein, either RNA or DNA, and possibly lipid.
C) protein and either RNA or DNA, but no lipid.
D) protein and both RNA and DNA, but no lipid.
E) protein, and possibly lipid.

A) virulent or lytic phage.
B) latent phage.
C) lysogenic phage.
D) dormant phage.
E) temperate phage.

A) The entire virus.
B) Only the enzymes necessary for replication.
C) The nucleic acid.
D) The nucleic acid and capsid.
E) The capsid only.

A) temperate phages.
B) lytic phages.
C) virulent phages.
D) segmented phages.
E) bacteriophages.

A) is called a capsomere, AND is involved in the recognition of host cell receptors by non-enveloped viruses.
B) is called a capsid, AND is involved in the recognition of host cell receptors by non-enveloped viruses.
C) protects the nucleic acid, AND is involved in the recognition of host cell receptors by non-enveloped viruses.
D) is called a capsomere, protects the nucleic acid, AND is involved in the recognition of host cell receptors by non-enveloped viruses.
E) is called a capsid, protects the nucleic acid, AND is involved in the recognition of host cell receptors by non-enveloped viruses.

A) prokaryotic cell wall.
B) capsomere.
C) eukaryotic cytoplasmic membrane.
D) cytoplasm.
E) eukaryotic cell wall.

A) T9
B) T4
C) beta
D) gamma
E) lambda

A) Bacillus
B) Icosahedral
C) Helical
D) Complex
E) These are all virus shapes.

A) is completely self-assembly 
B) is completely dependent on scaffolds.
C) may involve some self-assembly AND may involve the use of scaffolds.
D) may involve some self-assembly AND is completely dependent on scaffolds.
E) is completely self-assembly AND is never dependent on scaffolds.

A) penetration, transcription, attachment, replication of nucleic acid and protein, assembly, release.
B) attachment, penetration, transcription, replication of nucleic acid and protein, assembly, release.
C) attachment, replication of nucleic acid and protein, penetration, transcription, assembly, release.
D) transcription, attachment, replication of nucleic acid and protein, assembly, penetration, release.
E) attachment, replication of nucleic acid and protein, assembly, penetration, transcription, release.

A) lysozyme is used to allow entry of the phage capsid.
B) the tail acts as a "hypodermic needle," injecting the phage DNA into the cell.
C) the protein fibers digest a hole in the cell wall.
D) the bacterial receptor molecules open a hole through the cell wall.
E) the intact phage enters the host by endocytosis.

A) coded for by host DNA.
B) coded for by phage DNA.
C) proteins normally present in the uninfected cell.
D) early proteins.
E) coded for by phage DNA AND early proteins.

A) transformation is taking place in the phage and this is transferred to the bacterium.
B) bacterial DNA has replaced critical viral DNA in the phage.
C) their virulence is dependent on the bacteria and virus replicating together.
D) the lytic genes are unable to enter during penetration and are shed outside the host.
E) viral DNA has replaced critical bacterial DNA in the phage.

A) They are immune to any further infection by any virus.
B) They are immune to infection by the same virus.
C) They may have new properties AND they respond to infection with the SOS response.
D) They respond to infection with the SOS response.
E) They are immune to infection by the same virus AND may have new properties.

A) dsDNA.
B) dsRNA.
C) positive ssRNA.
D) negative ssDNA.
E) positive ssDNA.

A) self-assembly.
B) matrix conversion.
C) lysogenic conversion.
D) prion protein.
E) phase variation.

A) only infect E. coli that have pili.
B) only infect E. coli lacking pili.
C) infect E. coli regardless of the presence of pili.
D) do not infect E. coli.
E) only infect Gram-negative E. coli.

A) They are extruded from the host cell.
B) They contain a negative-sense DNA strand.
C) Their DNA is transformed to dsDNA before replication and transcription occur.
D) All of the choices are correct.
E) None of the choices is correct.

A) 1 per host cell.
B) 5 per host cell.
C) 20 per host cell.
D) 200 per host cell.
E) 1,000 per host cell.

A) single-stranded DNA.
B) double-stranded DNA.
C) single-stranded RNA.
D) double-stranded RNA.
E) single-stranded RNA, OR single-stranded DNA.

A) may be lysogenic.
B) may be lytic.
C) enters a lysogenic or lytic life cycle shortly after entering the host cell.
D) may be lytic AND enters a lysogenic or lytic life cycle shortly after entering the host cell.
E) may be lysogenic AND enters a lysogenic or lytic life cycle shortly after entering the host cell.

A) A lysogen is a bacterial cell with an integrated prophage.
B) When integrated into host DNA, phage DNA is called a virophage.
C) Lambda is a good example of a lytic phage.
D) Lambda can be a lytic or a temperate phage.
E) A lysogen is a virus that has bacterial DNA in it.

A) the host's enzymes are used to make dsDNA.
B) the host's DNA polymerase uses the phage RNA as a template to make negative-sense DNA.
C) a phage-encoded DNA polymerase is used to make negative-sense RNA using the phage positive-sense RNA as a template.
D) a phage-encoded DNA polymerase is used to make DNA using the phage positive-sense RNA as a template.
E) a phage-encoded RNA polymerase is used to make DNA using the phage positive-sense RNA as a template.

A) destruction of certain bacterial genes AND destruction of the viral repressor through host protease activity.
B) destruction of the viral repressor through host protease activity AND complete lysis of the bacterial culture.
C) destruction of the viral repressor through host protease activity AND mutation of the DNA 
D) complete lysis of the bacterial culture, destruction of the viral genes, AND mutation of the DNA.
E) destruction of certain bacterial genes AND complete lysis of the bacterial culture.

A) the bacteria is frequently plated on new media.
B) certain phage genes are excised.
C) certain phage genes are repressed.
D) bacterial repressor genes are activated.
E) bacterial repressor genes are deactivated.

A) lysogenic viruses.
B) temperate phages.
C) filamentous phages.
D) lambda viruses.
E) helical phages.

A) the phage's ability to synthesize an enzyme that integrates its DNA into the host's chromosome.
B) the phage's ability to synthesize enzymes that allow it to enter the bacterium.
C) similarity in RNA nucleotides in both the phage and the bacterial host.
D) the similarity in enzyme metabolism in the phage and the bacterial cell.
E) the phage's ability to synthesize enzymes to enter the bacterium AND similar RNA nucleotides in both.

A) lysis.
B) inversion.
C) extrusion.
D) excising.
E) endocytosis.

A) M13
B) T4
C) Lambda
D) TMV
E) T2

A) presence of specific receptor molecules on the host cell.
B) internal metabolic temperature of the host cell.
C) nutrition of the host cell.
D) stage of cell cycle of the host cell.
E) culture conditions of the host cell.

A) 1 day.
B) 30 minutes.
C) 10 minutes.
D) 1 minute.
E) 45 seconds.

A) incomplete.
B) mutated.
C) defective.
D) vegetative.
E) carcinogenic.

A) never use spikes for attachment to host cells.
B) have a lipid bilayer membrane containing various proteins.
C) are surrounded by an additional layer of carbohydrate.
D) surround the boundary of a host cell.
E) are difficult to destroy using detergents.

A) A virus that has lost some of its genetic material, and therefore cannot infect a new target cell.
B) A virus that has lost some of its genetic material, and therefore cannot replicate within a new target cell.
C) A virus that lacks the ability to replicate independently of its host cell and cannot survive.
D) A virus that cannot attach to its host cell and therefore cannot enter the target cell.
E) A virus that lacks a prophage, cannot enter a host cell, and cannot survive.

A) a single type of phage can destroy a wide range of strains of the same pathogen.
B) of the increasing problem of antibiotic resistance in pathogens.
C) lysed bacteria pose no threat to a person's health.
D) a single phage can be genetically engineered to infect many different species of bacteria.
E) of the increasing problem of antibiotic resistance in people.

A) -virus.
B) -viridae.
C) -viscous.
D) -eieio.
E) -virum.

A) DNA and RNA and protein.
B) DNA or RNA, and protein.
C) protein located in the nucleus.
D) nucleic acid in the ribosome.
E) DNA or RNA, lipid, and protein.

A) 2
B) 5
C) 7
D) 13
E) 6

A) is replicated.
B) is transcribed.
C) may get degraded by bacterial nucleases.
D) may integrate into the host chromosome.
E) All of the choices are correct.

A) 7
B) 5
C) 4
D) 2
E) 6

A) viral life cycles.
B) forms of nucleic acid.
C) types of viral envelopes.
D) shapes of viruses.
E) types of bacteriophages.

A) may contain several pieces of RNA.
B) have an icosahedral-shaped capsid.
C) are linked together before budding out.
D) have an envelope that has several components.
E) may contain RNA with undefined regions in it.

A) locale AND genus
B) genus AND species
C) disease AND species
D) disease AND locale
E) disease AND genus

A) Conjugation and lysogeny
B) Lysogeny and transduction
C) Extrusion and transformation
D) Extrusion and lysogeny
E) Extrusion and lysis

A) it involves the random transmission of any gene.
B) it involves the transfer of a few specific genes.
C) it involves a defective virus.
D) it only involves genes near the viral DNA integration site.
E) it involves temperate phages.

A) the release of the virions depletes the cell of energy.
B) the virus releases enzymes that lyse the cell.
C) functions necessary for cell survival are not carried out and the cell dies.
D) the virus RNA and cellular protein interact to kill the cell.
E) the viruses release lysozyme which destroys the host cell wall.

A) lack of spikes for attachment.
B) lack of specific receptors on the host cell.
C) phagocytosis of the virus by the host cell.
D) the presence of the viral envelope.
E) immunity in the host cell.

A) integration of viral DNA into host DNA.
B) separation of viral nucleic acid from the capsid.
C) disintegration of host DNA.
D) addition of a lipid membrane to the virus.
E) lysis of the host cell.

A) hepatitis B.
B) hepatitis A.
C) chickenpox.
D) herpes.
E) influenza.

A) extrusion.
B) budding.
C) fission.
D) fusion.
E) endocytosis.

A) enzymes.
B) carbohydrates.
C) steroids.
D) matrix proteins.
E) phospholipids.

A) is by endocytosis.
B) is by fusion.
C) involve entry of the entire nucleocapsid.
D) differs because bacteriophages leave the capsid outside the cell, while animal virus entry involves the entry of the whole nucleocapsid.
E) differs because animal viruses leave the capsid outside the cell, while bacteriophage entry involves the entry of the whole nucleocapsid.

A) Picornaviridae.
B) Enterovirus.
C) Enteroviridae.
D) Picornavirus.
E) Rhinoviridae.

A) carbohydrates AND spike proteins.
B) spike proteins AND enzymes.
C) spike proteins AND matrix proteins.
D) matrix proteins AND carbohydrates.
E) enzymes AND matrix proteins.

A) may have a persistent infection.
B) may be a source of infection.
C) usually show symptoms of the disease AND may be a source of infection.
D) have been cured of the infection.
E) may have a persistent infection AND may be a source of infection.

A) presence or absence of a nuclear membrane.
B) type of nucleic acid it contains.
C) disease the virus causes.
D) geographic area it is found.
E) shape of the viral nucleocapsid.

A) glycoproteins.
B) proteins.
C) carbohydrates.
D) nucleic acid.
E) lipids.

A) constantly produced.
B) only produced during reactivation.
C) produced very slowly.
D) continually being slowly budded out.
E) always detectable in the infected person.

A) ssDNA.
B) dsDNA.
C) ssRNA.
D) dsRNA.
E) protein and RNA.

A) polio AND herpes.
B) herpes AND measles.
C) measles AND chickenpox.
D) chickenpox AND polio.
E) herpes AND chickenpox.

A) a tail.
B) the envelope.
C) spikes.
D) a capsid.
E) a membrane.

A) penetration.
B) production.
C) endocytosis.
D) fusion.
E) budding.

A) from the host cytoplasmic membrane as they exit the host.
B) from a newly constructed viral-derived membrane.
C) from the nuclear membrane as they exit the host.
D) from endoplasmic reticulum in the host.
E) from the host peptidoglycan as they exit.

A) acute.
B) balanced.
C) determinant.
D) persistent.
E) fatal.

A) Replication
B) Self-assembly
C) Translation
D) Maturation
E) All of the answer choices are correct.